Discovery Early Career Researcher Award - Grant ID: DE160100614
Funder
Australian Research Council
Funding Amount
$363,612.00
Summary
Evolutionary genomics and origin of the molluscan biomineralisation toolkit. The project aims to use new genomes from understudied lineages of Mollusca to identify the genes involved in shell formation (biomineralisation) and infer their function and evolutionary history. The ability of molluscs to biofabricate intricate and robust skeletal structures from sea water is encoded in their genomes. Understanding the ancestral biomineralisation toolkit is of great interest to materials science, which ....Evolutionary genomics and origin of the molluscan biomineralisation toolkit. The project aims to use new genomes from understudied lineages of Mollusca to identify the genes involved in shell formation (biomineralisation) and infer their function and evolutionary history. The ability of molluscs to biofabricate intricate and robust skeletal structures from sea water is encoded in their genomes. Understanding the ancestral biomineralisation toolkit is of great interest to materials science, which seeks to replicate molluscan biomineralisation in vitro for biomedical and other applications. Understanding the toolkit is an important first step toward synthetic biology techniques to 'print' structures like bones in vitro. Moreover, new genomic resources from molluscs will be of interest to researchers in numerous fields.Read moreRead less
Improving access to phylogenomic resources for under-resourced species: a new look at existing tools. This project will have an impact on our understanding of how to most effectively use existing genomic resources to benefit a wider range of species and to better design new genomic resources. By doing so, improved access to genomic resources will be provided to species that currently have few options.
Resolving insect evolution. Our poor understanding of the evolution of insects, life’s most successful group, is a huge gap in our knowledge of nature. By analysing genomic data the project will resolve the insect evolutionary tree and discover what drove insect evolution. This will expand our knowledge of how evolution works - a vital part of conserving our biological diversity.
Real-time phylogenetics for food-borne outbreak surveillance. The project aims to introduce, for the first time, real-time evolutionary analysis of agricultural pathogens so that outbreaks affecting crops and the food supply can be managed precisely and rapidly. An expert team will implement a large-scale data analytics framework in user-friendly software that integrates Australian infectious disease genomics data with global data. Underpinning this work are new theory and algorithms that apply ....Real-time phylogenetics for food-borne outbreak surveillance. The project aims to introduce, for the first time, real-time evolutionary analysis of agricultural pathogens so that outbreaks affecting crops and the food supply can be managed precisely and rapidly. An expert team will implement a large-scale data analytics framework in user-friendly software that integrates Australian infectious disease genomics data with global data. Underpinning this work are new theory and algorithms that apply Sequential Monte Carlo to update phylogenetic analyses continuously as new data arrives. Expected outcomes include new knowledge of statistical algorithms for evolutionary analysis, relevant to biological disciplines beyond infectious disease; and enhanced capacity for infectious disease analysis. Read moreRead less
Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this ....Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this project include improved methods for merging fossils into the tree of life and for reconstructing the ecology and morphology of ancestors on phylogenetic trees. This should provide significant benefits, such as a coherent evolutionary context for informing research on marsupial biology, ecology and conservation.Read moreRead less
Uncovering vertebrate lifespan biodiversity with whole genome sequencing. This project aims to integrate existing data on the genetic mechanisms of lifespan evolution in model systems with a novel combination of whole genome sequencing and comparative phylogenomics to reveal the common genomic signatures of lifespan evolution in vertebrates. Expected outcomes include a perspective on the evolution of lifespan, a topic of major health interest for Australia and the rest of the developed world. Th ....Uncovering vertebrate lifespan biodiversity with whole genome sequencing. This project aims to integrate existing data on the genetic mechanisms of lifespan evolution in model systems with a novel combination of whole genome sequencing and comparative phylogenomics to reveal the common genomic signatures of lifespan evolution in vertebrates. Expected outcomes include a perspective on the evolution of lifespan, a topic of major health interest for Australia and the rest of the developed world. This will provide significant benefits, such as long-term implications for aging research, with possible business applications. It will also increase Australia’s visibility and competitiveness in the developing field of bioinformatics.Read moreRead less
Genome dynamics following plastid endosymbiosis. Plastid endosymbiosis events (enslavement of an algal cell inside of a host cell to form a plastid) are difficult to pinpoint because the genomic data required for a broad array of species are rarely available. Furthermore, the classical method used to infer endosymbiotic gene transfers is being criticised. This project will elucidate the origin of chlorarachniophyte and dinoflagellate plastids and characterise the genome dynamics following endosy ....Genome dynamics following plastid endosymbiosis. Plastid endosymbiosis events (enslavement of an algal cell inside of a host cell to form a plastid) are difficult to pinpoint because the genomic data required for a broad array of species are rarely available. Furthermore, the classical method used to infer endosymbiotic gene transfers is being criticised. This project will elucidate the origin of chlorarachniophyte and dinoflagellate plastids and characterise the genome dynamics following endosymbiosis. It uses densely sampled genome data obtained with high-throughput sequencing technologies. Simulation studies will be used to evaluate methods for inferring endosymbiotic gene transfer and alignment-free methods will be used to improve phylogenomic pipelines.Read moreRead less
To eat or not to eat? How symbiotic bacteria manipulate the phagocytic behaviour of their eukaryotic host. Bacteria often live in close association with eukaryotic cells, ranging from simple amoeba to humans. This project will identify key factors that control their interactions and will yield important information on the evolution of beneficial or harmful relationships.